red lion P16 User manual

Category
Measuring, testing & control
Type
User manual

This manual is also suitable for

-0.0
+0.6
-0.000
+0.024
-0.0
+0.6
-0.000
+0.024
(45 )
1.772
(45 )
1.772
(9.4)
0.37
4.17 (105.9)
1.95
1.95
(49.5)
(49.5)
2
2
1O
O
1
A
A
R
MA
N
%
W
P
%
1.76 (44.7)
11
5
12
1.76
(44.7)
1413
4
3
2
1
10
9
8
7
6
1
MODELS T16 & P16 - TEMPERATURE/PROCESS CONTROLLERS
GENERAL DESCRIPTION
The Model T16 Controller accepts signals from a variety of temperature
sensors (thermocouple or RTD), while the Model P16 Controller accepts either a
0 to 10 VDC or 0/4 to 20 mA DC input signal. Both controllers can provide an
accurate output control signal (time proportional or DC Analog Output) to
maintain a process at a setpoint value. Dual 4-digit displays allow viewing of the
process/temperature and setpoint simultaneously. Front panel indicators inform
the operator of the controller and output status. The comprehensive programming
allows these controllers to meet a wide variety of application requirements.
MAIN CONTROL
The controller operates in the PID Control Mode for both heating and
cooling, with on-demand auto-tune, that establishes the tuning constants. The
PID tuning constants may be fine-tuned through the front panel and then locked
out from further modification. The controller employs a unique overshoot
suppression feature, that allows the quickest response without excessive
overshoot. Switching to Manual Mode provides the operator direct control of the
output. The controller may also be programmed to operate in On/Off mode with
adjustable hysteresis.
ALARMS
Optional alarm(s) can be configured independently for absolute high or low
acting with balanced or unbalanced hysteresis. They can also be configured for
deviation and band alarm. In these modes, the alarm trigger values track the
setpoint value. Adjustable alarm hysteresis can be used for delaying output
response. The alarms can be programmed for Automatic or Latching operation.
A selectable standby feature suppresses the alarm during power-up until the
temperature stabilizes outside the alarm region.
ANALOG OUTPUT OPTION
The optional DC Analog Output (10 V or 20 mA) can be configured and
scaled for control or re-transmission purposes. The programmable output update
time reduces valve or actuator activity.
PC PROGRAMMING KIT
The optional TP16KIT contains a programming module with a 9 pin RS232
connector, cable and Crimson, a Windows
®
based configuration software. The
software allows downloading, uploading and storage of T16 and P16 program
files. All controllers have a communications port that allows configuration by
PC even without controller power connected. Controller calibration is also
possible using the software when the proper calibration equipment and
controller power is connected.
CONSTRUCTION
The controller is constructed of a lightweight, high impact, black plastic
textured case and bezel with a clear display window. The front panel meets
NEMA 4X/IP65 specifications when properly installed. In applications that do
not require protection to NEMA 4X, multiple controllers can be stacked
horizontally or vertically. Modern surface-mount technology, extensive testing,
plus high immunity to noise interference makes the controller extremely reliable
in industrial environments.
SAFETY SUMMARY
All safety related regulations, local codes and instructions that appear in the
manual or on equipment must be observed to ensure personal safety and to
prevent damage to either the instrument or equipment connected to it. If
equipment is used in a manner not specified by the manufacturer, the protection
provided by the equipment may be impaired.
Do not use the controller to directly command motors, valves, or other actuators
not equipped with safeguards. To do so can be potentially harmful to persons or
equipment in the event of a fault to the controller. An independent and redundant
temperature limit indicator with alarm outputs is strongly recommended.
PID CONTROL WITH REDUCED OVERSHOOT
T16 ACCEPTS TC AND RTD
P16 ACCEPTS 0-10 V AND 0/4-20 mA SIGNALS
ON DEMAND AUTO-TUNING OF PID SETTINGS
DC ANALOG OUTPUT (OPTIONAL)
USER PROGRAMMABLE FUNCTION BUTTON
PC OR FRONT PANEL PROGRAMMING
PC CONFIGURABLE WITH TP16KIT
DIMENSIONS In inches (mm)
PANEL CUT-OUT
UL Recognized Component,
File #E156876
CAUTION: Risk of Danger.
Read complete instructions prior to
installation and operation of the unit.
CAUTION: Risk of electric shock.
Bulletin No. T/P16-L
Drawing No. LP0486
Released 8/13
Tel +1 (717) 767-6511
Fax +1 (717) 764-0839
www.redlion.net
2
INPUT SPECIFICATIONS
1. SENSOR INPUT:
Sample Period: 100 msec (10 Hz rate)
Step Response Time: 300 msec typical, 400 msec max to within 99% of final
value with step input.
Failed Sensor Response:
Main Control Output(s): Programmable preset output
Display: “OPEN”
Alarms: Upscale drive
Analog Output: Upscale drive when assigned to retransmitted input.
Normal Mode Rejection: >40 dB @ 50/60 Hz
Common Mode Rejection: >120 dB, DC to 60 Hz
Overvoltage Protection: 120 VAC @ 15 sec max
2. RTD INPUTS: (T16 only)
Type: 2 or 3 wire
Excitation: 150 µA typical
Lead Resistance: 15 max per input lead
Resolution: 1° or 0.1° for all types
TYPE INPUT TYPE RANGE STANDARD
385
100 platinum,
Alpha = .00385
-200 to +600°C
-328 to +1112°F
IEC 751
392
100 platinum,
Alpha = .003919
-200 to +600°C
-328 to +1112°F
No official
standard
672
120 nickel,
Alpha = .00672
-80 to +215°C
-112 to +419°F
No official
standard
Ohms Linear Resistance 0.0 to 320.0 N/A
3. THERMOCOUPLE INPUTS: (T16 only)
Types: T, E, J, K, R, S, B, N, C, and Linear mV
Input Impedance: 20 M for all types
Lead Resistance Effect: 0.25 µV/
Cold Junction Compensation: Less than ±1°C typical (1.5°C max) error
over ambient temperature range.
Resolution: 1° for types R, S, B and 1° or 0.1° for all other types
TYPE DISPLAY RANGE
WIRE COLOR
STANDARD
ANSI BS 1843
T
-200 to +400°C
-328 to +752°F
(+) Blue
(-) Red
(+) White
(-) Blue
ITS-90
E
-200 to 750°C
-328 to +1382°F
(+) Violet
(-) Red
(+) Brown
(-) Blue
ITS-90
TYPE DISPLAY RANGE
WIRE COLOR
STANDARD
ANSI BS 1843
J
-200 to +760°C
-328 to +1400°F
(+) White
(-) Red
(+) Yellow
(-) Blue
ITS-90
K
-200 to +1250°C
-328 to +2282°F
(+) Yellow
(-) Red
(+) Brown
(-) Blue
ITS-90
R
0 to +1768°C
+32 to +3214°F
No
standard
(+) White
(-) Blue
ITS-90
S
0 to +1768°C
+32 to +3214°F
No
standard
(+) White
(-) Blue
ITS-90
B
+149 to +1820°C
+300 to +3308°F
No
standard
No
standard
ITS-90
N
-200 to +1300°C
-328 to +2372°F
(+) Orange
(-) Red
(+) Orange
(-) Blue
ITS-90
C
W5/W6
0 to +2315°C
+32 to +4199°F
No
standard
No
standard
ASTM
E988-96
mV
-5.00 mV to
56.00mV
N/A N/A N/A
4. SIGNAL INPUT: (P16 only)
INPUT RANGE ACCURACY * IMPEDANCE
MAX
CONTINUOUS
OVERLOAD
RESOLUTION
10 VDC
(-1 to 11)
0.30 % of
reading
+0.03V
1 M 50 V 10 mV
20 mA DC
(-2 to 22)
0.30 % of
reading
+0.04V
10 100 mA 10 µA
*Accuracies are expressed as ± percentages over 0 to 50 °C ambient range
after 20 minute warm-up.
5. TEMPERATURE INDICATION ACCURACY: (T16 only)
± (0.3% of span, +1°C) at 23 °C ambient after 20 minute warm up. Includes
NIST conformity, cold junction effect, A/D conversion errors and linearization
conformity.
Span Drift (maximum): 130 PPM/°C
6. USER INPUT: (Only controllers with alarms have a user input terminal.)
Internally pulled up to +7 VDC (100 K), V
IN
MAX
= 35 V, V
IL
= 0.6 V max,
V
IH
= 1.5 V min, I
OFF
= 40 µA max
Response Time: 120 msec max
Functions: Programmable
GENERAL SPECIFICATIONS
1. DISPLAY: 2 Line by 4-digit, LCD negative image transmissive with
backlighting.
Top (Process) Display: 0.3" (7.6 mm) high digits with red backlighting.
Bottom (Parameter) Display: 0.2" (5.1 mm) high digits with green
backlighting.
2. ANNUNCIATORS:
Status Annunciators:
O1 - Main control output is active.
O2 - Cooling output is active (when Alarm 2 is used for cooling).
A1 - Alarm 1 output is active.
A2 - Alarm 2 output is active.
°F, °C - Temperature units.
%PW - Output power percentage is shown in Bottom display.
MAN - Controller is in Manual Mode.
R - Ramping Setpoint indicator.
% - Percent indicator (P16 models only).
Display Messages:
 - Measurement exceeds + sensor range
 - Measurement exceeds - sensor range
 - Open sensor is detected (T16 only)
 - Shorted sensor is detected (RTD only)
 - Measurement exceeds controller limits (P16 only)
 - Display value exceeds + display range
 - Display value exceeds - display range
3. POWER:
Line Voltage Models:
85 to 250 VAC, 50/60 Hz, 8 VA
Low Voltage Models:
DC Power: 18 to 36 VDC, 4 W
AC Power: 24 VAC, ±10%, 50/60 Hz, 7 VA
4. CONTROLS: Three rubber push buttons for modification and setup of
controller parameters. One additional button (F1) for user programmable
function. One external user input (models with alarms) for parameter lockout
or other user programmable functions.
5. MEMORY: Nonvolatile E
2
PROM retains all programmable parameters.
6. ISOLATION LEVEL:
AC power with respect to all other I/O: 250 V working (2300 V for 1 min.)
Sensor input to analog output: 50 V working (500 V for 1 minute)
Relay contacts to all other I/O: 300 V working (2300 V for 1 minute)
DC power with respect to sensor input and analog output: 50 V working
(500 V for 1 minute)
7. CERTIFICATIONS AND COMPLIANCES:
CE Approved
EN 61326-1 Immunity to Industrial Locations
Emission CISPR 11 Class A
IEC/EN 61010-1
RoHS Compliant
UL Recognized Component: File #E156876
Type 4X Enclosure rating (Face only)
IP65 Enclosure rating (Face only)
IP20 Enclosure rating (Rear of unit)
Refer to EMC Installation Guidelines section of the bulletin for additional
information.
8. ENVIRONMENTAL CONDITIONS:
Operating Temperature Range: 0 to 50°C
Storage Temperature Range: -40 to 80°C
Operating and Storage Humidity: 85% max relative humidity (non-
condensing) from 0°C to 50°C
Vibration to IEC 68-2-6: Operational 5 to 150 Hz, 2 g.
Shock to IEC 68-2-27: Operational 20 g (10 g relay).
Altitude: Up to 2000 meters
9. CONNECTION: Wire-clamping screw terminals
10. CONSTRUCTION: Black plastic alloy case and collar style panel latch.
Panel latch can be installed for vertical or horizontal instrument stacking.
Black plastic textured bezel with transparent display window. Controller
meets NEMA 4X/IP65 requirements for indoor use when properly installed.
Installation Category II, Pollution Degree 2.
11. WEIGHT: 6.3 oz (179 g)
3
OUTPUT SPECIFICATIONS
1. CONTROL AND ALARM OUTPUTS:
Relay Output:
Type: Form A
Contact Rating: 3 A @ 250 VAC or 30 VDC (resistive load)
Life Expectancy: 100,000 cycles at max. load rating
(Decreasing load and/or increasing cycle time, increases life expectancy)
Logic/SSR Output (main control output only):
Rating: 45 mA max @ 4 V min., 7 V nominal
2. MAIN CONTROL:
Control: PID or On/Off
Output: Time proportioning or DC Analog
Cycle Time: Programmable
Auto-Tune: When selected, sets proportional band, integral time, derivative
time, and output dampening time. Also sets input filter and (if applicable)
cooling gain.
Probe Break Action: Programmable
3. ALARMS: (optional) 2 relay alarm outputs.
Modes:
None
Absolute High Acting (Balanced or Unbalanced Hysteresis)
Absolute Low Acting (Balanced or Unbalanced Hysteresis)
Deviation High Acting
Deviation Low Acting
Inside Band Acting
Outside Band Acting
Heat (Alarm 1 on Analog Output models only)
Cool (Alarm 2)
Reset Action: Programmable; automatic or latched
Standby Mode: Programmable; enable or disable
Hysteresis: Programmable
Sensor Fail Response: Upscale
Annunciator: “A1” and “A2” programmable for normal or reverse acting
4. COOLING: Software selectable (overrides Alarm 2).
Control: PID or On/Off
Output: Time proportioning
Cycle Time: Programmable
Proportional Gain Adjust: Programmable
Heat/Cool Deadband Overlap: Programmable
5. ANALOG DC OUTPUT: (optional)
Self-powered (Active)
Action: Control or retransmission
Update Rate: 0.1 to 250 sec
OUTPUT
RANGE **
ACCURACY * COMPLIANCE RESOLUTION
0 to 10 V
0.3% of FS
+ ½ LSD
10 k min 1/8000
0 to 20 mA
0.3% of FS
+ ½ LSD
500 max 1/8000
4 to 20 mA
0.3% of FS
+ ½ LSD
500 max 1/6400
* Accuracies are expressed as ± percentages over 0 to 50 °C ambient range
after 20 minute warm-up.
** Outputs are independently jumper selectable for either 10 V or 20 mA. The
output range may be field calibrated to yield approximately 5% overrange
and a small underrange (negative) signal.
ORDERING INFORMATION
MODEL NO. MAIN CONTROL 2 ALARMS & USER INPUT
PART NUMBERS
18-36 VDC/24 VAC 85 to 250 VAC
T16
Relay T1610010 T1610000
Relay Yes T1611110 T1611100
Logic/SSR T1620010 T1620000
Logic/SSR Yes T1621110 T1621100
Analog Out * Yes T1641110 T1641100
P16
Relay P1610010 P1610000
Relay Yes P1611110 P1611100
Logic/SSR P1620010 P1620000
Logic/SSR Yes P1621110 P1621100
Analog Out * Yes P1641110 P1641100
* Analog out may be used for retransmitted signals. When using analog output for retransmitted signals, AL1
becomes main control O1, if selected for heating in the analog out models.
ACCESSORIES
MODEL NO. DESCRIPTION PART NUMBERS
TP16
Programming Kit 1 : Includes Software, Comms Module w/
9-pin connector and cable, and 115 VAC Power Adapter
TP16KIT1
Programming Kit 2 : Includes Software, Comms Module w/
9-pin connector and cable
TP16KIT2
RLY
External SSR Power Unit (for Logic/SSR models) RLY50000
25 A Single Phase Din Rail Mount Solid State Relay RLY60000
40 A Single Phase Din Rail Mount Solid State Relay RLY6A000
Three Phase Din Rail Mount Solid State Relay RLY70000
4
EMC INSTALLATION GUIDELINES
Although Red Lion Controls Products are designed with a high degree of
immunity to Electromagnetic Interference (EMI), proper installation and wiring
methods must be followed to ensure compatibility in each application. The type
of the electrical noise, source or coupling method into a unit may be different
for various installations. Cable length, routing, and shield termination are very
important and can mean the difference between a successful or troublesome
installation. Listed are some EMI guidelines for a successful installation in an
industrial environment.
1. A unit should be mounted in a metal enclosure, which is properly connected
to protective earth.
2. Use shielded cables for all Signal and Control inputs. The shield connection
should be made as short as possible. The connection point for the shield
depends somewhat upon the application. Listed below are the recommended
methods of connecting the shield, in order of their effectiveness.
a. Connect the shield to earth ground (protective earth) at one end where the
unit is mounted.
b. Connect the shield to earth ground at both ends of the cable, usually when
the noise source frequency is over 1 MHz.
3. Never run Signal or Control cables in the same conduit or raceway with AC
power lines, conductors, feeding motors, solenoids, SCR controls, and
heaters, etc. The cables should be run through metal conduit that is properly
grounded. This is especially useful in applications where cable runs are long
and portable two-way radios are used in close proximity or if the installation
is near a commercial radio transmitter. Also, Signal or Control cables within
an enclosure should be routed as far away as possible from contactors, control
relays, transformers, and other noisy components.
4. Long cable runs are more susceptible to EMI pickup than short cable runs.
5. In extremely high EMI environments, the use of external EMI suppression
devices such as Ferrite Suppression Cores for signal and control cables is
effective. The following EMI suppression devices (or equivalent) are
recommended:
Fair-Rite part number 0443167251 (RLC part number FCOR0000)
Line Filters for input power cables:
Schaffner # FN2010-1/07 (Red Lion Controls # LFIL0000)
6. To protect relay contacts that control inductive loads and to minimize radiated
and conducted noise (EMI), some type of contact protection network is
normally installed across the load, the contacts or both. The most effective
location is across the load.
a. Using a snubber, which is a resistor-capacitor (RC) network or metal oxide
varistor (MOV) across an AC inductive load is very effective at reducing
EMI and increasing relay contact life.
b. If a DC inductive load (such as a DC relay coil) is controlled by a transistor
switch, care must be taken not to exceed the breakdown voltage of the
transistor when the load is switched. One of the most effective ways is to
place a diode across the inductive load. Most RLC products with solid state
outputs have internal zener diode protection. However external diode
protection at the load is always a good design practice to limit EMI.
Although the use of a snubber or varistor could be used.
RLC part numbers: Snubber: SNUB0000
Varistor: ILS11500 or ILS23000
7. Care should be taken when connecting input and output devices to the
instrument. When a separate input and output common is provided, they
should not be mixed. Therefore a sensor common should NOT be connected
to an output common. This would cause EMI on the sensitive input common,
which could affect the instrument’s operation.
Visit RLC’s web site at http://www.redlion.net/Support/InstallationConsiderations.
html for more information on EMI guidelines, Safety and CE issues as they
relate to Red Lion Controls products.
+5V
A
A
A
D
+7V
D
+5V
+22V
-6.2V
D
O
+22V
O
O
+7V
D
+5V
D
DA
+7V
+7V
+7V
+7V
D/A
CONV.
20M
Ω
976K
Ω
20K
Ω
.01µF
100K
Ω
100K
Ω
+
-
+
-
25.5
Ω
100K
Ω
8.2
Ω
4.02K
Ω
10
Ω
(FRONT)
10V
(REAR)
20mA
(+) O1
(-) O1
POWER
SUPPLY
OPTION
POWER
SUPPLY
POWER
CONTROL
CIRCUITRY
POWER
INPUT
11
-V/-I
A/D
Converter
USER IN
+0.7V
P16 0-10V
P16 0-20 mA
T16 RTD EXC
+V/+I
A2/O2 COMM
A2/O2 N.O.
A1/O1 COMM
A1/O1 N.O. *
Process
Circuitry
INPUT COMM
T16 TC+
Keypad
(-) O1
(+) O1
12
8
1
10
10
9
9
6
7
6
7
7
6
2
3
4
5
O
ANALOG OUTPUT
MODELS
SSR DRIVE
MODELS
ALARM OUTPUT MODELS
MAIN CONTROL
OUTPUT
E Memory
2
BLOCK DIAGRAM
*A1 becomes main control O1, if selected for heating in the
analog out models.
5
1.0 Setting the JumperS (AnAlog output modelS only)
To insure proper operation, the Analog Output jumpers must be set to the same
range selected in programming Module 2-OP. The default jumper setting
is for 20 mA. The default setting in Module 2-OP is 4-20 mA. To
access the jumpers, insert a flat-blade screwdriver between the front
panel and the side case slot. This should disengage the top and
bottom front panel latches from the case grooves. Pull the
front panel assembly with the controller boards out of
the case. The jumpers are located inside the
controller on the left board along the back
top section.
20mA (Both jumpers toward
the rear of the unit)
10V (Both jumpers toward
the front of the unit)
VIEW FROM TOP OF UNIT
02
F1
RDY
A2
01
A1
°
%PW
MAN
%
YORK, PA. MADE IN U.S.A.
RED LION CONTROLS
2.0 inStAlling the Controller
Instructions:
1. Prepare the panel cutout to the proper dimensions.
2. Remove the panel latch from the controller. Discard the cardboard sleeve.
3. Carefully remove the center section of the panel gasket and discard. Slide the
panel gasket over the rear of the controller, seating it against the lip at the
front of the case.
4. Insert the controller into the panel cutout. While holding the controller in
place, push the panel latch over the rear of the controller, engaging the tabs
of the panel latch in the farthest forward slot possible.
5. To achieve a proper seal, tighten the panel latch
screws evenly until the controller is snug in the
panel, torquing the screws to approximately 7
in-lb (79 N-cm). Overtightening can result in
distortion of the controller, and reduce the
effectiveness of the seal.
Note: The installation location of the controller is
important. Be sure to keep it away from heat
sources (ovens, furnaces, etc.) and away from
direct contact with caustic vapors, oils, steam, or
any other process by-products in which exposure
may affect proper operation.
-0.0
+0.6
-0.000
+0.024
-0.0
+0.6
-0.000
+0.024
(45 )
1.772
(45 )
1.772
1413
6
7
8
10
9
LATCHING
BEZEL
LATCHING
PANEL LATCH
PANEL
MOUNTING
SCREW
TABS
SLOTS
PANEL
PANEL GASKET
Multiple Controller Stacking
The controller is designed to allow for close spacing of multiple controllers
in applications that do not require protection to NEMA 4X. Controllers can be
stacked either horizontally or vertically. For vertical stacking, install the panel
latch with the screws to the sides of the controller. For horizontal stacking, the
panel latch screws should be at the top and bottom of the controller. The
minimum spacing from centerline to centerline of controllers is 1.96" (49.8
mm). This spacing is the
same for vertical or
horizontal stacking.
Note: When stacking
controllers, provide
adequate panel
ventilation to ensure
that the maximum
operating temperature
range is not exceeded.
1.96 (49.8)
MIN
STANDARD
PANEL
CUT-OUT
IF NEMA 4 IS NOT REQUIRED,
THIS PANEL MATERIAL MAY BE REMOVED.
2.39 (60.7)
MAX.
1.96 (49.8)
MAX.
2.39 (60.7)
1.96 (49.8)
MAX
MAX
The T16 and P16 controllers meet NEMA 4X/IP65 requirements for indoor
use to provide a watertight seal in steel panels with a minimum thickness of
0.09", or aluminum panels with a
minimum thickness of 0.12". The
controllers are designed to be
mounted into an enclosed panel.
The bezel assembly must be in
place during installation of
the controller.
6
3.0 Wiring the Controller
WIRING CONNECTIONS
All wiring connections are made to the rear screw terminals. When wiring the
controller, use the numbers on the label and those embossed on the back of the
case, to identify the position number with the proper function.
All conductors should meet voltage and current ratings for each terminal.
Also, cabling should conform to appropriate standards of good installation, local
codes and regulations. It is recommended that power (AC or DC) supplied to the
controller be protected by a fuse or circuit breaker. Strip the wire, leaving
approximately 1/4" (6 mm) bare wire exposed (stranded wires should be tinned
with solder). Insert the wire under the clamping washer and tighten the screw
until the wire is clamped tightly.
CONTROLLER POWER CONNECTIONS
For best results, the power should be relatively “clean” and within
the specified limits. Drawing power from heavily loaded circuits or
from circuits that also power loads that cycle on and off should be
avoided. It is recommended that power supplied to the controller be
protected by a fuse or circuit breaker.
DC-DC+
1211
+-
ACAC
~~
1211
INPUT CONNECTIONS
For two wire RTDs, install a copper sense lead of the same gauge and length
as the RTD leads. Attach one end of the wire at the probe and the other end to
input common terminal. Complete lead wire compensation is obtained. This is
the preferred method. If a sense wire is not used, then use a jumper. A
temperature offset error will exist. The error may be compensated by
programming a temperature offset.
RTD 10
TC+9
COMM 8
RTD
TC+
10
9
COMM 8
TC+
TC-
10V
20mA
10
9
COMM
8
DC+ VOLTAGE
DC-
DC+ CURRENT
CONTROL AND ALARM OUTPUT CONNECTIONS
VDC
VAC
RTD and Resistance Thermocouple and Millivolt
Voltage and Current
4
3
2N.O.
COMM.
5
COMM.
N.O.
LOAD
LOAD
AC/DC
POWER
POWER
AC/DC
A2/O2
A1/O1*
7
6
AC/DC
POWER
LOAD
(-) O1
(+) O1
7
6
AC POWER
SSR
(-) O1
(+) O1
POWER
UNIT
+
-
AC
AC
Alarm Models Main Control Relay Models
Main Control Logic/SSR Models
ANALOG DC OUTPUT CONNECTIONS
USER INPUT CONNECTIONS
81
USER
COMM.
INPUT
*A1 becomes main control O1, if selected for
heating in the analog out models.
7
6
CONTROLLER,
+ V/I
RECORDER
- V/I
7
FRONT PANEL KEYS
The F1 key is pressed to exit (or escape) directly to the start of the
Display Loop. While in the Display Loop, the F1 key can be pressed to
activate its programmed function.
The Loop key is pressed to advance to the next parameter, to activate
a changed selection/value, and when held for three seconds, enter the
Hidden Loop.
The Arrow keys are used to scroll through parameter selections/
values and in the Configuration Loop they are used to scroll to the
appropriate Parameter Module.
4.0 revieWing the Front KeyS And diSplAy
L
A
BJ
2
2
1O
O
1
A
A
R
MAN
%
W
P
%
TOP DISPLAY
BOTTOM DISPLAY
ILLUMINATES WHEN OUTPUT POWER
PERCENTAGE IS SHOWN.
ILLUMINATES WHEN CONTROLLER
IS IN MANUAL MODE.
ILLUMINATES WHEN PERCENT
IS SELECTED. (P16 ONLY)
ILLUMINATES WHEN °F or °C
IS SELECTED. (T16 ONLY)
DISPLAYS TEMPERATURE/PROCESS VALUE.
ALSO DISPLAYS PARAMETER NAME IN
CONFIGURATION LOOP.
DISPLAYS SETPOINT OR % OUTPUT POWER.
ALSO DISPLAYS PARAMETER NAME AND VALUE
IN DISPLAY AND HIDDEN LOOPS OR
PARAMETER VALUE IN CONFIGURATION LOOP.
ILLUMINATES WHEN COOLING
(SECONDARY) OUTPUT IS ACTIVE.
ILLUMINATES WHEN MAIN
CONTROL OUTPUT IS ACTIVE.
ILLUMINATES WHEN ALARM 2
OUTPUT IS ACTIVE.
ILLUMINATES WHEN ALARM 1
OUTPUT IS ACTIVE.
FLASHES WHEN RAMPING
SETPOINT IS ACTIVE.
5.0 progrAmming: diSplAy loop
DISPLAY LOOP
Note: Setpoint and Output Power are the only parameters visible in the Display Loop with Factory Settings. The remaining parameters can
be selected for the Display Loop within Module 3.
Parameter availability is model and programming dependent.
DISPLAY LOOP
At power up, all display segments light, and then the programmed input type
and the controllers software version will flash. Then the Temperature/Process
Value is shown in the top display, and the Setpoint Value is shown in the bottom
display. This is the Display Loop. If the Setpoint is hidden or locked, the Display
Loop will default to Output Power. If Output Power is also hidden or locked out,
the bottom display is blank. During programming, the F1 key can be pressed to
return the controller to this point. (Only in the Display Loop will the F1 key
perform the user F1In function programmed in Input Module 1I.)
When the A is pressed the controller advances to the next parameter in the
Display Loop. Except for Setpoint and % Output Power, the bottom display
alternates between the parameter name and its selection/value. The arrow keys
are pressed to change the selection/value for the shown parameter. The new
selection/value is activated when the A is pressed. Display Loop parameters
may be locked out or hidden in Lockout Module 3-LC. Some parameters are
model and programming dependent.
FRONT DISPLAY
ENDS AND RETURNS TO START OF DISPLAY LOOP.
ADVANCES TO NEXT PARAMETER.
CHANGES SELECTION/VALUE.



TOP DISPLAY
TEMP/PROCESS
BOTTOM DISPLAY
PARAMETER
SELECTION/VALUE
F1
8
SETPOINT VALUE (SP1) *
SETPOINT VALUE (SP2) *
 to 


2
2

% OUTPUT POWER *
1 to 1
 to 
Typically, the controller is operating with the Setpoint value in the bottom
display. There is no annunciator nor parameter indication for Setpoint in the
Display Loop. The parameter name alternates with the setpoint value in the
Hidden Loop. The Setpoint value can be changed, activated and stored by
pressing the arrow keys. This is the only parameter that can be configured as
read only in the Display Loop, but read/write in the Hidden Loop. It is possible
to store a second Setpoint value that can be selected in the Hidden Loop, by the
F1 key or the user input. Both Setpoint values are limited by the Setpoint Low
and High Limits in Input Module 1-IN.
The % Output Power is shown with the %PW annunciator. The parameter
name alternates with the % Output Power value in the Hidden Loop. While the
controller is in Automatic Mode, this value is read only. When the controller is
placed in Manual Mode, the value can be changed, activated and stored by
pressing the arrow keys. For more details on % Output Power, see Control
Mode Explanations.
12
In
INTEGRAL TIME
to  seconds
Integral action shifts the center point position of the proportional band to
eliminate error in the steady state. The higher the integral time, the slower the
response. The optimal integral time is best determined during PID Tuning. If
time is set to zero, the previous Integral output power value is maintained.
Offset Power can be used to provide Manual Reset.


DERIVATIVE TIME
to  seconds per repeat
Derivative time helps to stabilize the response, but too high of a derivative
time, coupled with noisy signal processes, may cause the output to fluctuate too
greatly, yielding poor control. Setting the time to zero disables derivative action.
ALARM 1 VALUE
 to 
On models with alarms, the value for Alarm 1 can be entered here. The value
is either absolute (absolute alarm types) or relative to the Setpoint value
(deviation and band alarm types.) When Alarm 1 is programmed for  or
n, this parameter is not available. For more details on alarms, see Alarm
Module 4-AL.

F
OUTPUT POWER OFFSET
When the Integral Time is set to zero and the controller is in the Automatic
Mode, this parameter will appear after % Output Power. It is also shown with
the %PW annunciator illuminated. The power offset is used to shift the
proportional band to compensate for errors in the steady state. If Integral Action
is later invoked, the controller will re-calculate the internal integral value to
provide “bumpless” transfer and Output Power Offset will not be necessary.


PROPORTIONAL BAND
 to 
(% of full input range)
The proportional band should be set to obtain the best response to a process
disturbance while minimizing overshoot. A proportional band of 0.0% forces
the controller into On/Off Control with its characteristic cycling at Setpoint. For
more information, see Control Mode and PID Tuning Explanations.
* Alternating indication only used in the Hidden Loop.
ALARM 2 VALUE
 to 
On models with alarms, the value for Alarm 2 can be entered here. The value
is either absolute (absolute alarm types) or relative to the Setpoint value
(deviation and band alarm types.) When Alarm 2 is programmed for  or
n, this parameter is not available. For more details on alarms, see the Alarm
Module .
The values shown for the displays are the factory settings.
T16
P16

1
T16
P16

2
T16
P16


T16
P16
1 to 1
6.0 progrAmming: hidden loop
HIDDEN LOOP
Note: Parameters shown bold are the only parameters visible in the Hidden Loop with Factory Settings. Setpoint and Output Power are
factory set for the Display Loop. The remaining parameters can be selected for the Hidden Loop within Module 3.
Parameter availability is model and programming dependent.
FRONT DISPLAY
ENDS AND RETURNS TO START OF DISPLAY LOOP.
ADVANCES TO NEXT PARAMETER.
CHANGES SELECTION/VALUE.



TOP DISPLAY
TEMP/PROCESS
BOTTOM DISPLAY
PARAMETER
SELECTION/VALUE

F1
To enter Hidden Loop, press A for 3 seconds.
HIDDEN LOOP
When A is pressed and held for three seconds, the controller advances to the
Hidden Loop. The Temperature/Process Value is shown in the top display. The
bottom display alternates between the parameter and its selection/value. B or
J is pressed to change the selection/value for the shown parameter. The new
selection/value is activated after A is pressed. When L is pressed, the
controller returns to the Display Loop and stores changed selection/values to
permanent memory. Hidden Loop parameters may be locked out in Lockout
Module . Some parameters are model and programming dependent.

1

ACCESS CODE
1 to 12
If the Access Code is set from 1 to 125, in Lockout Module , Access
Code will appear here. By entering the proper Code, access to the Hidden Loop
is permitted. With the factory setting of 0, Access Code will not appear in the
Hidden Loop. A universal code of 111 can be entered to gain access,
independent of the programmed code number.


SETPOINT RAMP RATE
 to 

nF
CONTROL MODE TRANSFER
 
SETPOINT SELECT
1 or 2
The SPSL function allows the operator to switch from or to, setpoint 1 and
setpoint 2. In the Display Loop, there is no annunciator indicating the selected
Setpoint, however, the selected Setpoint value is displayed and activated.
In Automatic Mode, the percentage of Output Power is automatically
determined by the controller. In Manual/User  Mode, the percentage of
Output Power is adjusted manually while in the Display Loop. The Control
Mode can also be transferred through the F1 Key or User Input. For more
information, see Control Mode Explanations.
The setpoint ramp rate can reduce sudden shock to the process and reduce
overshoot on startup or after setpoint changes, by ramping the setpoint at a
controlled rate. R annunciator flashes while ramping. With the T16, the ramp rate
is always in tenths of degrees per minute, regardless of the resolution chosen for
the process display. With the P16, the ramp rate is in least-significant (display
units) digits per minute. A value of 0.0 or 0 disables setpoint ramping. Once the
ramping setpoint reaches the target setpoint, the setpoint ramp rate disengages
until the setpoint is changed again. If the ramp value is changed during ramping,
the new ramp rate takes effect. If the setpoint is ramping prior to starting Auto-
Tune, the ramping is suspended during Auto-Tune and then resumed afterward.
Deviation and band alarms are relative to the target setpoint, not the ramping
setpoint. A slow process may not track the programmed setpoint rate. At power
up, the ramping setpoint is initialized at the ambient temperature/process value.
9
10
7.0 progrAmming: ConFigurAtion loop




 


LOOP
HIDDEN DISPLAY
LOOP
PARAMETERS
INPUT
MODULE MODULE
OUTPUT
PARAMETERS
LOCKOUT
PARAMETERS
MODULE
COOLING
PARAMETERS
MODULE
FACTORY
SERVICE
MODULE
ALARM
PARAMETERS
MODULE
CONFIGURATION LOOP
FRONT DISPLAY
ENDS AND RETURNS TO START OF DISPLAY LOOP.
RETURNS TO DISPLAY LOOP.
ADVANCES TO NEXT MODULE.



TOP DISPLAY
TEMP/PROCESS
BOTTOM DISPLAY
CNFP/MODULE

ENTERS MODULE OR AT
CNFP/NO
F1
To access the Configuration Loop, press the up key when F/ is displayed
in the Hidden Loop. The arrow keys are used to select the parameter module
(1-9). To enter a specific module press A while the module number is
displayed. In the Configuration Loop, F will alternate with the parameter
number in the bottom display. The Temperature/Process Value is shown in the
top display.
After entering a parameter module, press A to advance through the
parameter names in the module. To change a parameters selection/value, press
the arrow keys while the parameter is displayed. In the modules, the top display
shows the parameter name, and the bottom display shows the selection/value.
Use A to enter any selection/values that have been changed. The change is not
committed to permanent memory until the controller is returned to the Display
Loop. If a power loss occurs before returning to the Display Loop, the new
values must be entered again.
At the end of each module, the controller returns to F/. At this location,
pressing A again returns the display to the the Display Loop. Pressing the Up
key allows re-entrance to the Configuration Loop. Whenever L is pressed, n
momentarily appears as the parameters are stored to permanent memory and the
controller returns to the Display Loop.
FRONT DISPLAY
F1
ENDS AND RETURNS TO START
AT RETURNS TO DISPLAY LOOP.
ADVANCES SELECTION/VALUE.


TOP DISPLAY
PARAMETER
BOTTOM DISPLAY
SELECTION/VALUE
ADVANCES TO NEXT PARAMETER OR
OF DISPLAY LOOP.

12

ALARMS RESET
12
With alarm models, the alarms can be manually reset. The up key resets
Alarm 1 and the down key resets Alarm 2.

ACCESS CODE
1 to 12
If the Access Code is set from -1 to -125, in Lockout Module , Access
Code will appear here. By entering the proper Code, access to the Configuration
Loop is permitted (with a negative Code value, the Hidden Loop can be
accessed without the use of a code). With the factory setting of 0 or with an
active User Input configured for Program Lock (), Access Code will not
appear here. An active user input configured for Program Lock () always
locks out the Configuration Loop, regardless of Access Code.


AUTO-TUNE START
 
The Auto-Tune procedure of the controller sets the Proportional Band,
Integral Time, Derivative Time, Digital Filter, Control Output Dampening
Time, and Relative Gain (Heat/Cool) values appropriate to the characteristics of
the process. This parameter allows front panel starting  or stopping  of
Auto-Tune. For more information, see PID Tuning Explanations.
11
7.1 module 1 - input pArAmeterS (1-IN) t16 only
 

  
INPUT
TYPE
TEMP
SCALE
DECIMAL
RESOLUTION
DIGITAL
FILTERING OFFSET
SHIFT/
HIGH LIMIT
SETPOINTSETPOINT
LOW LIMIT

INPUT
USER

F1 KEY
FUNCTION


PARAMETER MENU


INPUT TYPE
F

TEMPERATURE SCALE
F Fahrenheit
 Celsius
SELECTION TYPE SELECTION TYPE

T TC

N TC

E TC

C TC
j
J TC
I
Linear mV

K TC

RTD 385

R TC
2
RTD 392

S TC
2
RTD 672

B TC
I
Linear Ohms
Select the input type that corresponds to the input sensor.
Select either degrees Fahrenheit or Celsius. For linear mV and ohms input
types, this has no effect. If changed, adjust related parameter values, as the
controller does not automatically convert them.

DECIMAL RESOLUTION
to  for temperature and resistance inputs
 for mV inputs
Select whole degrees, or tenths of degrees for Temperature display, Setpoint
values, and related parameters. For Linear Resistance inputs I, the same
parameter selections apply in ohms or tenths of an ohm. For mV inputs I,
only hundredths of a mV resolution is available.

SHIFT/OFFSET
 to  degrees
This value offsets the controller’s temperature display value by the entered
amount. This is useful in applications in which the sensor cannot provide the
actual temperature signal due to mounting constraints, inaccuracy, etc.

SETPOINT LOW LIMIT
 to 
The controller has a programmable low setpoint limit value to restrict the
setting range of the setpoint. Set the limit so that the setpoint value cannot be
set below the safe operating area of the process.

I
SETPOINT HIGH LIMIT
 to 
The controller has a programmable high setpoint limit value to restrict the
setting range of the setpoint. Set the limit so that the setpoint value cannot be
set above the safe operating area of the process.

In
USER INPUT FUNCTION (OPTIONAL)
The controller performs the selected User Input function (User Input
available only on models with alarms), when the User terminal 1 is connected
(pulled low) to Common terminal 8.
No Function: No function is performed.
Program Lock: The Configuration Loop is locked, as long as activated
(maintained action).
Integral Action Lock: The integral action of the PID computation is disabled
(frozen), as long as activated (maintained action).
Auto/Manual Select: This function selects (maintained action) Automatic
(open) or Manual Control (activated).
Setpoint 1 or 2 Select: This function selects (maintained action) Setpoint
1(open) or Setpoint 2 (activated) as the active setpoint.
Setpoint Ramp Disable: The setpoint ramping feature is disabled, as long as
activated (maintained action). Any time the user input is activated with a
ramp in process, ramping is aborted.
Reset Alarms: Active alarms are reset, as long as activated (maintained action).
Active alarms are reset until the alarm condition is cleared and triggered
again (momentary action).
1
F
DIGITAL FILTERING
= least to = most
The filter is an adaptive digital filter that discriminates between measurement
noise and actual process changes. If the signal is varying too greatly due to
measurement noise, increase the filter value. If the fastest controller response is
needed, decrease the filter value.
SELECTION FUNCTION SELECTION FUNCTION

No Function

Setpoint 1 or 2 Select

Program Lock

Setpoint Ramp Disable
I
Integral Action Lock

Reset Both Alarms
nF
Auto/Manual Select
12
7.1 module 1 - input pArAmeterS (1-IN) p16 only
 
 


INPUT
TYPE
PERCENT
SYMBOL
DECIMAL
RESOLUTION
ROUNDING
INCREMENT
INPUT
VALUE 1
DISPLAY
VALUE 1



SETPOINT
LOW LIMIT

SETPOINT
HIGH LIMIT
F1 KEY
FUNCTION


USER
INPUT
DIGITAL
FILTERING
DISPLAY
VALUE 2
INPUT
VALUE 2
 
A
A
PARAMETER MENU


INPUT TYPE


PERCENT ANNUNCIATOR
 On
 Off
This only illuminates the % annunciator. It does not perform any type of
percent function, but is useful in applications that have been scaled in percent.
1
n
ROUNDING INCREMENT
1 to 1
In steps of 1 least significant digit,
regardless of decimal point.
Rounding selections other than 1 cause the process value display to round to
the nearest rounding increment selected. (For example, rounding of 5 causes 122
to round to 120 and 123 to round to 125.) Rounding starts at the least significant
digit of the process value. Setpoint values, Setpoint limits, Alarm values, Input
Scaling values, and Analog Scaling values are not affected by rounding.

1
DISPLAY VALUE SCALING POINT 1
 to 
Enter the first coordinate Display Value by using the arrow keys.

I1
INPUT VALUE SCALING POINT 1
 to 2 mA
 to 1 V
For Key-in Method, enter the first coordinate Input Value by using the arrow
keys. To allow the P16 to “learn” the signal, use the Applied Method. For Applied
Method, press L. The ° annunciator is turned on to indicate the applied method.
Adjust the applied signal level externally until the appropriate value appears
under I1. Using either method, press A to store the value for I1. (The
controller can be toggled back to the Key-in Method by pressing L before A.)


DECIMAL RESOLUTION
  
This selection affects the decimal point placement for the Process value, and
related parameters.
1
F
DIGITAL FILTERING
= least to = most
The filter is an adaptive digital filter that discriminates between measurement
noise and actual process changes. If the signal is varying too greatly due to
measurement noise, increase the filter value. If the fastest controller response is
needed, decrease the filter value.

F1In
F1 KEY FUNCTION
The controller performs the selected F1 Key Function, when L is pressed
while in the Display Loop. In any other loop or module location, pressing L
will perform an escape to the Display Loop.
No Function: No function is performed.
Auto/Manual Select: This function toggles (momentary action) the controller
between Automatic and Manual Control.
Setpoint 1 or 2 Select: This function toggles (momentary action) the controller
between Setpoint 1 and Setpoint 2.
Reset Alarms: This function can be used to reset one or both of the alarms
when activated (momentary action) The alarm will remain reset until the
alarm condition is cleared and triggered again.
Reset Both Alarms

Setpoint 1 or 2 Select

Reset Alarm 2
2
Auto/Manual Select
nF
Reset Alarm 1
1
No Function

FUNCTIONSELECTIONFUNCTIONSELECTION
Voltage
Current


TYPESELECTION
Select the input type that corresponds to the input signal.
SCALING
To scale the controller, two scaling points are necessary. Each scaling point has
a coordinate pair of Display Values and Input Values. It is recommended that the
two scaling points be at the low and high ends of the input signal being measured.
Process value scaling will be linear between and continue past the entered points
to the limits of the input range. (Factory settings example will display 0.0 at 4.00
mA input and display 100.0 at 20.00 mA input.) Reverse acting indication can be
accomplished by reversing the two signal points or the Display value points, but
not both. If both are reversed, forward (normal) acting indication will occur. In
either case, do not reverse the input wires to change the action.
1
2
DISPLAY VALUE SCALING POINT 2
 to 
Enter the second coordinate Display Value by using the arrow keys.
13
2
I2
INPUT VALUE SCALING POINT 2
 to 2 mA
 to 1 V
For Key-in Method, enter the second coordinate Input Value by using the
arrow keys. To allow the P16 to “learn” the signal, use the Applied Method. For
Applied Method, press L. The ° annunciator is turned on to indicate the
applied method. Adjust the applied signal level externally until the appropriate
value appears under I2. Using either method, press A to store the value for
I2. (The controller can be toggled back to the Key-in Method by pressing L
before A.)


SETPOINT LOW LIMIT
 to 
The controller has a programmable low setpoint limit value to restrict the
setting range of the setpoint. Set the limit so that the setpoint value cannot be
set below the safe operating area of the process.

I
SETPOINT HIGH LIMIT
 to 
The controller has a programmable high setpoint limit value to restrict the
setting range of the setpoint. Set the limit so that the setpoint value cannot be
set above the safe operating area of the process.

In
USER INPUT FUNCTION (OPTIONAL)
The controller performs the selected User Input function (User Input
available only on models with alarms), when the User terminal 1 is connected
(pulled low) to Common terminal 8.
No Function: No function is performed.
Program Lock: The Configuration Loop is locked, as long as activated
(maintained action).
Integral Action Lock: The integral action of the PID computation is disabled
(frozen), as long as activated (maintained action).
Auto/Manual Select: This function selects (maintained action) Automatic
(open) or Manual Control (activated).
Setpoint 1 or 2 Select: This function selects (maintained action) Setpoint
1(open) or Setpoint 2 (activated) as the active setpoint.
Setpoint Ramp Disable: The setpoint ramping feature is disabled, as long as
activated (maintained action). Any time the user input is activated with a
ramp in process, ramping is aborted.
Reset Alarms: Active alarms are reset, as long as activated (maintained action).
Active alarms are reset until the alarm condition is cleared and triggered
again (momentary action).
SELECTION FUNCTION SELECTION FUNCTION

No Function

Setpoint 1 or 2 Select

Program Lock

Setpoint Ramp Disable
I
Integral Action Lock

Reset Both Alarms
nF
Auto/Manual Select

F1In
F1 KEY FUNCTION
The controller performs the selected F1 key function, when L is pressed
while in the Display Loop. In any other loop or module location, pressing L
will perform an escape to the Display Loop.
No Function: No function is performed.
Auto/Manual Select: This function toggles (momentary action) the controller
between Automatic and Manual Control.
Setpoint 1 or 2 Selection: This function toggles (momentary action) the
controller between Setpoint 1 and Setpoint 2.
Reset Alarms: This function can be used to reset one or both of the alarms
when activated (momentary action). The alarm will remain reset until the
alarm condition is cleared and triggered again.
Reset Both Alarms

Setpoint 1 or 2 Select

Reset Alarm 2
2
Auto/Manual Select
nF
Reset Alarm 1
1
No Function

FUNCTIONSELECTIONFUNCTIONSELECTION
14
2

CYCLE TIME
 to 2 seconds
OUTPUT POWER DAMPENING
to 2 seconds
The Cycle Time is entered in seconds with one tenth of a second resolution.
It is the total time for one on and one off period of the time proportioning
control output O1. With time proportional control, the percentage of power is
converted into an output on-time relative to the cycle time value set. (If the
controller calculates that 65% power is required and a cycle time of 10.0
seconds is set, the output will be on for 6.5 seconds and off for 3.5 seconds.)
For best control, a cycle time equal to one-tenth or less, of the natural period of
oscillation of the process is recommended. When using the Analog Output
signal for control, the Cycle Time setting has no effect. If the O1 output is not
being used, a cycle time of 0 can be entered to prevent the output and indicator
from cycling.


CONTROL ACTION
 Direct (cooling)
 Reverse (heating)
This determines the control action for the PID loop. Programmed for direct
action (cooling), the output power will increase if the Process value is above the
Setpoint value. Programmed for reverse action (heating), the output power
decreases when the Process Value is above the Setpoint Value. For heat and cool
applications, this is typically set to reverse. This allows O1 or A1 (models with
Analog Output) to be used for heating, and A2/O2 to be used for cooling.

OUTPUT POWER LOWER LIMIT
to 1 percent O1
1 to 1 percent O1/O2
This parameter may be used to limit controller power at the lower end due to
process disturbances or setpoint changes. Enter the safe output power limits for
the process. If Alarm 2 is selected for cooling, the range is from -100 to +100%.
At 0%, both O1 and O2 are off; at 100%, O1 is on; and at -100%, O2 is on.
When the controller is in Manual Control Mode, this limit does not apply.
1
I
OUTPUT POWER UPPER LIMIT
to 1 percent O1
1 to 1 percent O1/O2
This parameter may be used to limit controller power at the upper end due to
process disturbances or setpoint changes. Enter the safe output power limits for
the process. If Alarm 2 is selected for cooling, the range is from -100 to +100%.
At 0%, both O1 and O2 are off; at 100%, O1 is on; and at -100%, O2 is on.
When the controller is in Manual Control Mode, this limit does not apply.
AUTO-TUNE CODE
fastest to 2 slowest
Prior to starting Auto-Tune, this code should be set to achieve the necessary
dampening level under PID Control. This value allows customization of the PID
values that Auto-Tune will calculate. For the process to be controlled aggressively
(fastest process response with possible overshoot), set the Auto-Tune Code to 0.
For the process to be controlled conservatively (slowest response with the least
amount of overshoot), set this value to 2. If the Auto-Tune Code is changed,
Auto-Tune needs to be reinitiated for the changes to affect the PID settings. For
more information, see PID Tuning Explanations Section.
F
SENSOR FAIL POWER LEVEL
This parameter sets the power level for the control outputs in the event of a
sensor failure. If Alarm 2 is not selected for cooling, the range is from 0% (O1
output full off) to 100% (O1 output full on). If A2 is selected for cooling, the
range is from -100 to +100%. At 0%, both O1 and O2 are off; at 100%, O1 is
on; and at -100%, O2 is on. The alarm outputs are upscale drive with an open
sensor, and downscale drive with a shorted sensor (RTD only), independent of
this setting. Manual Control overrides the sensor fail preset.
The Dampening Time, entered as a time constant in seconds, dampens
(filters) the calculated output power. Increasing the value increases the
dampening effect. Generally, dampening times in the range of one-twentieth to
one-fiftieth of the controllers integral time (or process time constant) are
effective. Dampening times longer than these may cause controller instability
due to the added lag effect.
ON/OFF CONTROL HYSTERESIS
1 to 2
The controller can be placed in the On/Off Control Mode by setting the
Proportional Band to 0.0%. The On/Off Control Hysteresis (balanced around
the setpoint) eliminates output chatter. In heat/cool applications, the control
hysteresis value affects both Output O1 and Output O2 control. It is suggested
to set the hysteresis band to Factory Setting prior to starting Auto-Tune. After
Auto-Tune, the hysteresis band has no effect on PID Control. On/Off Control
Hysteresis is illustrated in the On/Off Control Mode section.

1

T16
P16
2
2

T16
P16
7.2 module 2 - output pArAmeterS (2-OP)
CYCt OPLOOPAC OPHI OPFL OPdP CHYS
CYCLE
TIME
CONTROL
ACTION
OUTPUT
POWER CONTROL
ON/OFF
OUTPUT
POWER
2-OP
CNFP
UPDATE
ANAS
OUTPUT
ANALOG
ANUt
ANALOG ANALOG
ANHI
HIGH
ANLO
LOW
ANALOGSENSOR FAIL
POWER CODE
AUTO-TUNE
OUTPUT
ANALOG
tcod ANtP
LOW LIMITHIGH LIMIT
POWER
OUTPUT
LEVEL DAMPENING HYSTERESISRANGE ASSIGNMENT TIME SCALING SCALING
PARAMETER MENU
to 1 percent O1
1 to 1 percent O1/O2
15
2

ANALOG OUTPUT RANGE (OPTIONAL)
1 V 2 mA
2 mA
Select the type of output and range. The Analog output jumpers are factory
set to current. They must be changed if voltage output is desired. The Analog
output can be calibrated to provide up to approximately 5% over range
operation (0 mA current can only go slightly negative).

ANALOG UPDATE TIME (OPTIONAL)
to 2 seconds
= update rate of 0.1 second
The update time of the Analog Output can be used to reduce excess valve
actuator or pen recorder activity.

ACCESS CODE
12 to 12
I

I

I
I
I

The following parameters can be configured for , I, and I.


I


nF
I



The following parameters can be configured for  or I only.


ANALOG OUTPUT ASSIGNMENT (OPTIONAL)
This setting selects the parameter that the Analog Output will retransmit or
track.
ANALOG LOW SCALING (OPTIONAL)
-999 to 9999
The Analog Output assignment value that corresponds to 0 V, 0 mA or 4 mA
output as selected.
ANALOG HIGH SCALING (OPTIONAL)
-999 to 9999
The Analog Output assignment value that corresponds to 10 V or 20 mA
output as selected. An inverse acting output can be achieved by reversing the
low and high scaling points.
7.3 module 3 - loCKout pArAmeterS (3-LC)




 
SETPOINT
ACCESS
OUTPUT
POWER
PID
VALUES
SETPOINT
SELECT

ACCESS
CODE
ACCESS ACCESS
VALUES
ALARM
ACCESSACCESS


 


SETPOINT
RAMP
ACCESS
CONTROL
TRANSFER
ACCESS
AUTO-TUNE
START
ACCESS
RESET
ALARMS
ACCESS
PARAMETER MENU


1
I

In

Active Setpoint
SETPOINT
ACCESS
OUTPUT
POWER
ACCESS
PID VALUES
ACCESS
ALARM
VALUES
ACCESS
SETPOINT
SELECT
ACCESS
AUTO-TUNE
START
ACCESS
SETPOINT
RAMP
ACCESS
CONTROL
TRANSFER
ACCESS
RESET
ALARMS
ACCESS
Input Signal Retransmission
Main Control % Output Power
SELECTION DESCRIPTION
I
Display: accessible in Display Loop.
I
Hide: accessible in Hidden Loop.

Locked: not accessible in either loop.
 (SP only)
Display/read: read only in Display Loop,
but read/write in Hidden Loop.
Full access to Display, Hidden,
and Configuration Loops
1 to
12
Code necessary to access
Configuration Loop only.
1 to 12
Code necessary to access
Hidden and Configuration Loops.
16
7.4 module 4 - AlArm pArAmeterS (4-AL) (optionAl)
ACt1 rSt1
Lit1
Stb1
AL-1
ACt2 Lit2
ALARM 1
ACTION
ALARM 1
ANNUNCIATOR
ALARM 1
RESET ANNUNCIATOR
ALARM 2ALARM 2
ACTION
4-AL
CNFP
AHYS
HYSTERESIS
ALARM 1 & 2ALARM 1
VALUE RESET
ALARM 2
STANDBY
ALARM 2
rSt2 stb2
MODE
STANDBY
ALARM 1
MODE
AL-2
ALARM 2
VALUE
PARAMETER MENU
OFF
ON
AL + ½Hys
AL
AL - ½Hys
OFF
Absolute High Acting (Balanced Hys)
Hys
TRIGGER POINTS
ALARM
STATE
ALARM
STATE
OFF ON
Hys
SP + AL
SP
OFF
TRIGGER POINTS
Deviation High Acting (AL > 0)
ALARM
STATE
Hys
SP - AL
SP
SP + AL
Hys
TRIGGER POINTS
ON OFF OFFON ON
Band Inside Acting
OFF ON
AL + ½Hys
AL
AL - ½Hys
OFF
Absolute Low Acting (Balanced Hys)
TRIGGER POINTS
Hys
ALARM
STATE
ALARM
STATE
OFFON
Hys
SP - AL
SP
OFF
TRIGGER POINTS
Deviation Low Acting (AL > 0)
ALARM
STATE
OFF ON
Hys
AL
AL - Hys
OFF
TRIGGER POINTS
Absolute High Acting (Unbalanced Hys)
ALARM
STATE
OFF ON
Hys
AL + Hys
AL
OFF
TRIGGER POINTS
Absolute Low Acting (Unbalanced Hys)
ALARM
STATE
ON OFF
Hys
SP + (-AL)
SP
ON
TRIGGER POINTS
Deviation High Acting (AL< 0)
ALARM
STATE
ON
Hys
SP - AL
SP
OFF
SP + AL
ON
Hys
OFF OFF
TRIGGER POINTS
Band Outside Acting
ALARM ACTION FIGURES
Note: Hys in the above figures refers to the Alarm Hysteresis.
AVAILABLE ALARM ACTIONS

None
No action, the remaining Alarm
parameters are not available.
I
Absolute High
(balanced hysteresis)
The alarm energizes when the Process
Value exceeds the alarm value + 1/2
the hysteresis value.

Absolute Low
(balanced hysteresis)
The alarm energizes when the Process
Value falls below the alarm value -1/2
the hysteresis value.
I
Absolute High
(unbalanced hysteresis)
The alarm energizes when the Process
Value exceeds the alarm value.

Absolute Low
(unbalanced hysteresis)
The alarm energizes when the Process
Value falls below the alarm value.
I
Deviation High
Alarm 1 and 2 value tracks the
Setpoint value

Deviation Low
Alarm 1 and 2 value tracks the
Setpoint value
I
Band Acting
(inside)
Alarm 1 and 2 value tracks the
Setpoint value

Band Acting
(outside)
Alarm 1 and 2 value tracks the
Setpoint value

Heat (A1 Analog
models only)
If heating is selected, the remaining
Alarm 1 parameters are not available.

Cool
(A2 only)
If cooling is selected, the remaining
Alarm 2 parameters are not available.
17
n
Lit1
ALARM ANNUNCIATOR ALARM 1
With normal selection, the alarm annunciator indicates “on” alarm output 1.
With reverse selection, the alarm annunciator indicates “off” alarm output.

1
ALARM STANDBY ALARM 1
Standby prevents nuisance (typically low level) alarms after a power up or
setpoint change. After powering up the controller or changing the setpoint, the
process must leave the alarm region (enter normal non-alarm area of operation).
After this has occurred, the standby is disabled and the alarm responds normally
until the next controller power up or setpoint change.
ALARM HYSTERESIS

2
ALARM STANDBY ALARM 2
 Standby on
 Standby off
Standby prevents nuisance (typically low level) alarms after a power up or
setpoint change. After powering up the controller or changing the setpoint, the
process must leave the alarm region (enter normal non-alarm area of operation).
After this has occurred, the standby is disabled and the alarm responds normally
until the next controller power up or setpoint change.
ALARM VALUE ALARM 1
The alarm values are entered as process units or degrees. They can also be
entered in the Display or Hidden Loops. When the alarm is configured as
deviation or band acting, the associated output tracks the Setpoint as it is
changed. The value entered is the offset or difference from the Setpoint.

1
ALARM RESET MODE ALARM 1
In Automatic mode, an energized alarm turns off automatically after the
Temperature/Process value leaves the alarm region. In Latched mode, an
energized alarm requires an F1 key or user input alarm reset to turn off. After an
alarm reset, the alarm remains reset off until the trigger point is crossed again.
n
2
ALARM ANNUNCIATOR ALARM 2
n Normal
 Reverse
With normal selection, the alarm annunciator indicates “on” alarm output 2.
With reverse selection, the alarm annunciator indicates “off” alarm output.

2
ALARM RESET MODE ALARM 2
 Automatic
 Latched
In Automatic mode, an energized alarm turns off automatically after the
Temperature/Process value leaves the alarm region. In Latched mode, an
energized alarm requires an F1 key or user input alarm reset to turn off. After an
alarm reset, the alarm remains reset off until the trigger point is crossed again.
ALARM VALUE ALARM 2
The alarm values are entered as process units or degrees. They can also be
entered in the Display or Hidden Loops. When the alarm is configured as
deviation or band acting, the associated output tracks the Setpoint as it is
changed. The value entered is the offset or difference from the Setpoint.
 to 
The Hysteresis Value is either added to or subtracted from the alarm value,
depending on the alarm action selected. The same value applies to both alarms.
See the Alarm Action Figures for a visual explanation of how alarm actions are
affected by the hysteresis.
to 2
I
2
ALARM ACTION ALARM 2
Select the action for the alarms. See Alarm Action Figures for a visual
explanation.
 I  I 
I  I  

1
T16
P16
2
2
2
T16
P16
1
1

T16
P16
I
1
ALARM ACTION ALARM 1
Select the action for the alarms. See Alarm Action Figures for a visual
explanation.
II
II
n Normal
 Reverse
 Automatic
 Latched
 Standby on
 Standby off
 to 
18
CYCLE TIME
 to 2 seconds
This cycle time functions like the O1 Output Cycle Time but allows
independent cycle time for cooling. A setting of zero will keep output O2 off.
RELATIVE GAIN
 to 1
This defines the gain of the cooling relative to the heating. It is generally set
to balance the effects of cooling to that of heating. This is illustrated in the Heat/
Cool Relative Gain Figures. A value of 0.0 places the cooling output into On/
Off Control.
2
DEADBAND/OVERLAP
 to 
This defines the overlap area in which both heating and cooling are active
(negative value) or the deadband area between the bands (positive value). If a
heat/cool overlap is specified, the percent output power is the sum of the heat
power (O1) and the cool power (O2). If Relative Gain is zero, the cooling
output operates in the On/Off Control Mode, with the On/Off Control
Hysteresis  in Output Module 2 becoming the cooling output hysteresis.
The function of Deadband is illustrated in the Control Mode Explanations. For
most applications, set this parameter to 0.0 prior to starting Auto-Tune. After
the completion of Auto-Tune, this parameter may be changed.
7.5 module 5 - Cooling (SeCondAry) pArAmeterS (5-O2)
CYC2 db-2gAN2
COOLING
CYCLE
COOLING
RELATIVE
HEAT/COOL
DEADBAND/
5-O2
CNFP
OVERLAPTIME GAIN
PARAMETER MENU
To enable Cooling in Heat/Cool applications, the Alarm 2 Action must first
be set for Cooling. (For P16 Controllers, the cooling output is sometimes
referred to as secondary output.) When set to cooling, the output no longer
operates as an alarm but operates as a cooling output. The O2 terminals are the
same as A2, however a separate O2 annunciator indicates Cooling Operation.
Cooling output power ranges from -100% (full cooling) to 0% (no cooling,
unless a heat/cool overlap is used). The Power Limits in Output Module 2-OP
also limit the cooling power. In applications requiring only a Cooling output,
the main 01 output should be used.
2
2
1
2
TEMPERATURE
COOLHEAT
SETPOINT
-100%
O2
+100%
O1
2X PROPORTIONAL
BAND
OUTPUT
POWER ( )
%
O1
+100%
SETPOINT
DEADBAND
NEGATIVE VALUE
POWER ( )
OUTPUT
%
COOL
RELATIVE GAIN = .5
.512
RELATIVE GAIN
O2
-100%
TEMPERATURE
HEAT
TEMPERATURE
HEAT
SETPOINT
-100%
O2
+100%
O1
DEADBAND
POSITIVE VALUE
POWER ( )
OUTPUT
%
RELATIVE GAIN
21 .5
RELATIVE GAIN = .5
COOL
HEAT/COOL RELATIVE GAIN FIGURES
Heat/Cool Deadband = 0
Heat/Cool Deadband < 0
Heat/Cool Deadband > 0
19
The controller is fully calibrated from the factory. Recalibration is
recommended every two years by qualified technicians using appropriate
equipment. Calibration may be performed by using the front panel or with the
TP16KIT. The front panel method is explained below. (Refer to the TP16KIT
bulletin for calibration instructions using TP16KIT cable and software.)
Calibration may be aborted by disconnecting power to the controller before
exiting Factory Service Module F. In this case, the existing calibration
settings remain in effect.
Note: Allow the controller to warm up for 30 minutes minimum and follow
the manufacturers warm-up recommendations for the calibration source or
measuring device.
Cold Junction (T16)
Cold Junction calibration requires a thermocouple of known accuracy of
types T, E, J, K, C or N (connected to terminals 8 and 9) and a calibrated
external reference thermocouple probe measuring in °C with resolution to
tenths. The two probes should be brought in contact with each other or in some
way held at the same temperature. They should be shielded from air movement
and allowed sufficient time to equalize in temperature. (As an alternative, the
T16 thermocouple may be placed in a calibration bath of known temperature.)
If performing the millivolt calibration prior, verify that the correct input type is
configured in Input Module 1I before performing the following procedure.
(After the millivolt calibration the controller will default to type J.) If using RTD
only, the cold junction calibration need not be performed.
RTD Resistance (T16)
RTD calibration requires a precision 277.0 ohm resistor with an accuracy of
0.1 (or better). Connect a jumper between terminals 9 and 10 with a 0 ohm
jumper between 9 and 8 at 1 and the 277.0 ohm resistor between 9 and 8 at
2. If using thermocouple only, the RTD calibration need not be performed.
Input Calibration (P16)
Process calibration requires a precision signal source with an accuracy of
0.03% (or better) that is capable of generating 10.0 V connected to terminals 8
(COMM) and 9 (+10V) and 20.00 mA connected to terminals 8 (COMM) and
10 (20mA). The current calibration can be skipped by pressing A at the not
applicable prompts if using the controller for process voltage only.
CALIBRATION
7.5 module 9 FACtory ServiCe operAtionS (9-FS)

FACTORY
SERVICE CODE
 
Millivolt Calibration (T16)
Millivolt calibration requires a precision voltage source with an accuracy of
0.03% (or better) connected to terminals 8 (comm.) and 9 (+). When calibrating
the input, the millivolt calibration must be performed first, then the Cold Junction
or RTD Resistance.


PARAMETER MENU
PROMPT APPLY FRONT PANEL ACTION

Press J until , press A.

Press A.

Press A.

Press B for , press A.
1
0.0 ohm
After 5 seconds (minimum), press A.
2
277.0 ohm
After 5 seconds (minimum), press A.
PROMPT APPLY FRONT PANEL ACTION

Press J until , press A.

Press B for , press A.
1
0.0 ohm
After 5 seconds (minimum), press A.
2
2.5 V
After 5 seconds (minimum), press A.

5.0 V
After 5 seconds (minimum), press A.

7.5 V
After 5 seconds (minimum), press A.

10.0 V
After 5 seconds (minimum), press A.

0.0 mA
After 5 seconds (minimum), press A.

20.0 mA
After 5 seconds (minimum), press A.
PROMPT APPLY FRONT PANEL ACTION

Press J until , press A.

Press B for , press A.
1
0.0 ohm
After 5 seconds (minimum), press A.
2
14.0 mV
After 5 seconds (minimum), press A.

28.0 mV
After 5 seconds (minimum), press A.

42.0 mV
After 5 seconds (minimum), press A.

56.0 mV
After 5 seconds (minimum), press A.
PROMPT COMPARE FRONT PANEL ACTION

Press J until , press A.

Press A.

Press B for , press A.
Top display to
external
reference
Press B or J to adjust the
bottom display until the top
process display matches the
external reference then press A.
20


RESTORE FACTORY SETTINGS
Press and hold B to display  . Press A. The controller will display
 and then return to F. Press L to return to the Display Loop. This will
overwrite all user settings with Factory Settings.


NOMINAL CALIBRATION SETTINGS
Press and hold B to display  . Press A. Press and hold B to display
  again. Press A. The controller will then return to F. Press L to
return to the Display Loop. This will not overwrite any user settings but will
erase the controller calibration values. This procedure does not require any
calibration signals nor external meters. This can be used to clear calibration
error flag .
CAUTION: This procedure will result in up to ±10% reading error and the
controller will no longer be within factory specifications. For this reason, this
procedure should only be performed if meter error is outside of this range to
temporarily restore operation until the unit can be accurately calibrated.
For further technical assistance, contact technical support.
troubleShooting
Analog Output Calibration (T16 and P16)
Set the controller Analog jumpers to the output type being calibrated.
Connect an external meter with an accuracy of 0.05% (or better) that is capable
of measuring 10.00 V or 20.00 mA to terminals 6 (+V/I) and 7 (-V/I). The
voltage or current calibration that is not being used must be skipped by pressing
A until End appears.
PROMPT
EXTERNAL
METER
FRONT PANEL ACTION

Press J until , press A.

Press A.

Press A. (T16 only)

Press A. (T16 only)

Press B for , press A.
 
0.00 V
Press B or J until external meter
matches listing, press A.
1
10.00 V
Press B or J until external meter
matches listing, press A.

0.0 mA
Press B or J until external meter
matches listing, press A.
2
20.0 mA
Press B or J until external meter
matches listing, press A.
PROBLEM CAUSE REMEDIES
NO DISPLAY
1. Power off.
2. Brown-out condition.
3. Loose connection or improperly wired.
4. Bezel assembly not fully seated into rear of controller.
1. Check power.
2. Verify power reading.
3. Check connections.
4. Check installation.
CONTROLLER NOT WORKING
1. Incorrect setup parameters. 1. Check setup parameters.
2 IN DISPLAY
1. Loss of setup parameters due to noise spike or other
EMI event.
1. Press F1 to escape, then check controller accuracy.
a. Recalibrate controller. (See Factory Service Module code 77.)
b. Reset parameters to factory default settings.
 IN DISPLAY
1. Loss of calibration parameters due to noise spike or
other EMI event.
1. Press F1 to escape, then check controller accuracy.
a. Recalibrate controller. (See Factory Service Module code 77.)
b. Reset parameters to factory default settings.
 or  IN DISPLAY
1. Display value exceeds 4 digit display range.
2. Defective or miscalibrated cold junction circuit.
3. Loss of setup parameters.
4. Internal malfunction.
1. Press F1 to escape, then check controller accuracy.
a. Recalibrate controller. (See Factory Service Module code 77.)
b. Reset parameters to factory default settings.
 IN DISPLAY (T16)
1. Probe disconnected.
2. Broken or burned-out probe.
3. Corroded or broken terminations.
4. Excessive process temperature.
1. Change resolution to display whole number and verify reading.
2. Perform cold junction calibration.
3. Check setup parameters.
4. Perform Input calibration.
 IN DISPLAY (P16)
1. Input exceeds range of controller.
2. Incorrect input wiring.
3. Defective transmitter.
4. Internal malfunction.
1. Check input parameters.
2. Check input wiring.
3. Replace transmitter.
4. Perform input calibration.
 IN TOP DISPLAY
1. Input exceeds range of controller.
2. Temperature exceeds range of input probe.
3. Defective or incorrect transmitter or probe.
4. Excessive high temperature for probe.
5. Loss of setup parameters.
1. Check input parameters.
2. Change to input sensor with a higher temperature range.
3. Replace transmitter or probe.
4. Reduce temperature.
5. Perform input calibration.
 IN TOP DISPLAY
1. Input is below range of controller.
2. Temperature below range of input probe.
3. Defective or incorrect transmitter or probe.
4. Excessive low temperature for probe.
5. Loss of setup parameters.
1. Check input parameters.
2. Change to input sensor with a lower temperature range.
3. Replace transmitter or probe.
4. Raise temperature.
5. Perform input calibration.
 IN DISPLAY (T16)
1. RTD probe shorted. 1. Check wiring and/or replace RTD probe.
CONTROLLER SLUGGISH OR
NOT STABLE
1. Incorrect PID values.
2. Incorrect probe location.
1. See PID control.
2. Evaluate probe location.
 IN DISPLAY
1. Control output is damaged. 1. Return controller to factory for repair.
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red lion P16 User manual

Category
Measuring, testing & control
Type
User manual
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